Brake control means



Aug. 22, 1939- c. c. FARMER ET Al.

BRAKE CONTROL MEANS uw@ cam.

ATTORN EY I ug- 22, 1939- c. c. FARMER r- T Al.

BRAKE CONTROL MEANS 2 Sheets-Sheet 2 Filed April 20, 1957 o om @EN om@ Patented Aug. 22, 1939 UNITED STATES PATENT BRAKE CONTROL MEANS Application April 20, 1937, Serial No. 137,954

39 Claims.

This invention relates to brake control means and more particularly to brake control equipments for high speed trains whereby 'the brakes are automatically controlled both according to the speed of the train and according to the rate of retardation of the train.

Present-day high speed trains intended` to travel normally at speeds in excess of one hundred miles per hour, have presented numerous problems incidental to the adequate braking of the train whereby the train may be brought to a stopfrom a high speed over stopping distances substantially .the same as obtained in the case of present-day, lower speed, trains. Various brake control equipments for high speed trains have been proposed for automatically controlling the brakes on the trains, both according to the speed of the train and according to the rate of retardation of the train, so as to bring the train to a I v stop from avhigh speed within a reasonable stopping distance, comparable to stopping distances obtaining in the case of low speed trains, Without causing undue sliding of the wheels.

One of such brake control equipments for high speed trains is described and claimed in the copending application of George W. Baughman, one

n of the present joint applicants, now Patent 2,096,505 assigned to the assignee of the present application.

It is an object of the present invention to provide, in a brake control equipment for high speed4 trains of the character described in the copending application just mentioned, additional features including means for detecting wheel. slipf ping and for effecting automatically a reduction in the degree of the application to guard against and prevent a wheel sliding condition. It will be understood that the term slipping and the term sliding, as employed herein with respect to vehicle wheels have definitely diierent meanings. As used herein, the term wheel-slipping or wheel-slip refers to the condition wherein a vehicle wheel is slowing down from 'a rotative speed, corresponding to the speed of travel of the vehicle, to zero speed corresponding to the locked condition of the wheel. As used in the present application, the term wheel-sliding designates that condition of 'a vehicle wheel wherein it is locked against rotation while the vehicle continues to travel along the track rails.

Another object of our invention is to provide novel means for detecting a wheel-slipping or a wheel-sliding condition.

A further object'of our invention is to provide, in a brake control equipment of the character indicated in the rst mentioned object, a wheelslip detecting means associated with one wheeland-axle unit whichis more heavily braked than the other wheel-and-brake units of the train, for automatically controlling the brakes associated with the other wheel-and-axle units on the train to prevent the attainment of such a braking force thereon as would induce a wheel-slipping or a wheel-sliding condition.

The above objects and other and more specic objects which will appear in the subsequent description of our invention, are attained by means of illustrative embodiments hereinafter described and shown in the accompanying drawings, wherein,

Fig. 1 is a simplified diagrammatic view, with parts thereof in section, showing a brake control equipment for one car of a train and constituting one embodiment of my invention,

Fig. 2 is a fragmentary diagrammatic view,

villustrating one possible modified arrangement of BRIEF DESCRIPTION or EQUIPMENT SHOWN 1N FIG. 1

cylinders I0 and Illa, a speed-controlled or governor switch device I2, an inertia device hereinafter called a retardation controller I3, an automatic valve device I4, a manually operated brake valve device I5, and a fluid pressure operated switch device I 'I for controlling electrical connections, hereinafter described, to a suitable source of electrical energy such as a battery I8.

.Also included in the equipment are a main reservoir I9 charged with uid under pressure in well known manner'from a fluid compressor, not shown, an auxiliary reservoir 2i, the supply of fluid under pressure to and from which is controlled by the automatic valve device i4, a feed valve device 25 of standard construction and functioning in well known manner to regulate the pressure of. uid supplied from the main reservoir I9 into a pipe 26, hereinafterdesignated the feed valve pipe, to a substantially uniform pressure lower than that to which the reservoir I9 is charged, and a double check valve device 21,. Also provided are three pipes indicated as extending through all the cars of the train and herein- .after designated the main reservoir pipe 22, the

control pipe 23 and the brake pipe 2d.

There are also three train wires 3|, 32 and 33, hereinafter referred to as the high wire, the intermediate wire and the low wire, and according to our invention, energization and deenergization' of the train wires 3i, 32 and 33 is effected in the manner hereinafter described under the control of four electrical relay devices, hereinafter respectively called the wheel-slip relay 35, the low retardation relay 36, the high-retardation relay 3l and the speed relay 38;

The speed relay 3@ is controlled by the governor switch device i2 in the manner to be hereinafter described and the retardation relays @t and 3l are controlled by the retardation controller i3 in the manner .also hereinafter described. The wheel-slip relay is controlled by a differential relay lB, which is in turn controlled according to the current supplied thereto from two generators 3d and 45 driven, as through a pulley and belt arrangement in the manner shown, by rotation o the axles t and 9a, respectively.

in accordance with our invention, there are also' provided a magnet valve device 4S for releasing iuid under pressure from the brake cylinder iii, and a signal device, represented by a signal lamp ill, for indicating to the operator or engineman the'occurrence of a wheelrslipping or a wheel sliding condition o i the Wheels 8 and axle 9, both the magnet valve device 46 and the signal lamp il bgiang under thecontrol of the differential reay l The brake control equipment shown in Fig. 1

is adapted for use on trains of either the articlulated or the non-articulated type and only so much of the` equipment is shown as illustrates the operation thereof, the control of the brakes associated with wheels and wheel-and-axle units other than those shown being eifected in a manner similar to that described for the particular wheel-and-axle units shown.

Dn'rArwo DESCRIPTION or EQUIPMENT SHOWN IN F1o. l

(a) Brake control 'valve mechanism 11 The brake control valve mechanism il represents, in simplied form, a type of valve device described in detail and claimed in the copending application oi. Ellis E. Hewitt, now Patent 2,140,624 assignedto the assignee of the present application, certain parts of vthe valve device shown and described in the patent being omitted in the present application for the sake of simplicity.

In view of the fact that the valve mechanism ii is described in detail both as to construction and operation in Patent 2,140,624, the valve mechanism .i i is described herein only in a brief manner suiiicient to offer comprehension of the construction and operation thereof. Valve mechanism il is embodied in a sectional casing comprising a valve section 5|, a diaphragm section 52 secured to the valve section 5l as by bolts, not shown, two cover sections`53 and 54, respectively, secured to the diaphragm section 52 as by bolts, not shown, and a magnet valve section 55 secured to the valve section 5l as by bolts, not shown.

Formed in the casing section 5l is a chamber 5B which is constantly connected to the main reservoir pipe 22 through a branch pipe 51 and which contains a valve of the poppet type, hereinafter designated supply valve 58. Also formed in the casing section El is a chamber 59 which communicates with the brake cylinders lll and lila through a pipe and passage 6| and which contains a valve of the poppet type,l hereinafter designated the release valve S2, for controlling the venting of fluid under pressure from the chamber 59 and the brake cylinders i@ and lila through an exhaust port S3.

Operation of the supply valve and release valve is eiiected by rocking movement of s. lever 64 which is pivoted substantially intermediate the ends thereof as by a pin t5 on a slidable member t6.

The supply valve 58 is normally yieldingly seat by a biasing spring El, the inner end of the iluted stem of the'supply valve 5t engaging one end of a iluted spacer 58 slidable in the casing section 5 l, the other end of the spacer 68 engaging the lower end of the lever @d and urging it into substantial contact with an adjustable stop screw 59. lThe slidable member @t is yieldingly urged in the right-hand direction by a spring li so that the lever t@ is pivoted about its lower end. which is held between ,the stop screw t@ and the spacer 53.

The release valve 62 is carried on a stem 'l2 slidable in the casing section 5l and having two spaced shoulders connected by a reduced portion 'l0 which is straddled by the upper bifurcated end of the lever $8 in such manner that the upper end of the lever til is free to pivot at the upper end thereof between the spaced shoulders.

With the lower end of the lever 6d held between the spacer 58 and the stop screw GS, the shifting of the slidable member 66 in the right-hand direction by the spring li causes a shifting of the slidable stem i2 and the release valve -62 in the right-hand' direction to unseat the valve 62 and permit fluid under presume in the chamber 59 and in the brake cylinders to exhaust toatmos phere through the exhaust port 63.

When a force is applied to the right-hand end of the slidable member t6, as in the manner to be hereinafter described, and the slidable member d@ is urged in the lett-hand direction from the normal position shown, the spring tl 'holds the supply valve 53 seated and the spring ll yields so that the lever 5t is pivoted at its lower end and .the upper end shifted -in the left-hand direction to cause the release valve 62 to engage its lassociated valve seat to close off the connection from the chamber 59 to atmosphere through the exhaust port S3. Thereafter, as the slidable member d@ is further shifted in the left-hand direction, the lever t@ pivots at its upper bifurcated end and the lower end is shifted in the left-hand direction to eect unseating of the supply valve 58 against the force of the spring 61.'

When the force urging the slidable member 65 in the left-hand direction is relieved the spring t1 acts to seat the supply valve 58 and thus rock the lever 6&3 about the pin 55 to maintain the release valve t2 seated. After the supply valve 58 is seated, the spring 61 is no longer effective in rocking the lever 64 about the pin 65 and the spring 1| then acts to rock the lever 64 in a clockwise direction about the lower end thereof which is held between the spacer 68 and the stop screw 69 to effect unseating of the release valve 62.

Contained in the casing section 52 are a plurality of movable abutments or diaphragms 13, 14, 15 and 16 of successively smaller effective pressure areas in the order named, the dia- Dhragms being suitably clamped at the periphery thereof and disposed inl spaced coaxial relation.

The arrangement of the diaphragms 13, 14, 15 and 16 is such as to form a chamber 93 between the diaphragms 13 and '14, a chamber 94 between the diaphragms 14 and 15, a chamber 95 between the diaphragms 15 and 16 and a chamber 96 between the diaphragm 16 and the cover section 53, the latter chamber being constantly connect to the control pipe 23 through a pipe and passage 23a.

In order to maintain a minimum'spacing between the successive diaphragms, a cup-shaped spacer 11 is attached in suitable manner to one face of each of the diaphragms 14, 15 and 16 without perforating the diaphragm. The spacer 11 associated with the diaphragm 16 is adapted to engage the diaphragm 15, spacer 11 associated with the diaphragm 15 is adapted to engage the diaphragm 14 and the spacer 11 associated withV the diaphragm 14 is adapted to engagea follower plate 83 suitably attached to one face of the largest diaphragm 13 in a manner not necessitating perforation of the diaphragm. The follower plate 83 has an outwardly flared fiange or skirt 84 thereon which engages -a stop shoulder on the casing section 52 to limit the movement of 'the diaphragm 13 in the right-hand direction.

Associatedwith the face of the largest diaphragm 13 opposite to the follower plate 83 is a follower disc 18 which is slidably movable in a bore -19 in the casing section 5I, the bore 19 being open at the central portion thereof, through an opening 60, to the chamber 59. The righthand end of the slidable member 66 contained in the valve section 5| engages the follower disc 18 'and the spring 1| urging the slidable member 66 in the right-hand direction is thus effective to shift 'the diaphragms 13, 14, 15 and 16 in the right-hand direction until the flared flange 84 on the follower plate 83 engages the stop shoulder on Lthe casing section 52.

It will be observed that thediaphragms 13, 14, 15 and 16 are unconnected and that they may be moved collectively or individually.

Interposed between the chambers 93, 94 and 95 and the passage 23a are check valves 93a, 94a and 95a, respectively, which are yieldingly urgd into seated relation on an associated valve seat by lightly tensioned return springs |00. The check valves 93a, 94a and 95a are unseated to effect substantial equalization of the pressure in the chambers 93, 94 and 95 with the pressure in the passage 23a and in the control pipe 23 upon a reduction of the pressure in the control pipe 23 below the pressure in the chambers but are actuated to seated position to prevent the flow of fluid under pressure from the control pipe 23 and passage 23a to the chambers 93, 94 and 95 therepast upon an increase in the pressure in the control pipe 23. The purpose of the check valve 93a, 94a and 95a will be understood more clearly from subsequent description.

The magnet valve casing section 55 contains net three electromagnet valve devices, hereinafter y designated the high magnet valve device 0|, the intermediate magnet lvalve device |02 and the low magnet valve device |03, which function to control the supply and the release -of fluid under pressure from the chambers 93, 94 and 95 respectively.

The high magnet valve device |0| comprises a pair of oppositely seating valves, hereinafter called the supply valve |05 and the release valve |06, which are yieldingly urged by a spring |01 into seated and unseated positions, respectively, and which are actuated against the force of the spring |01 into unseated and seated positions, respectively, upon energization of an electromag- |08. With the release valve |06 unseated as shown, communication is established from a passage ||3, connected to the chamber 93 between the diaphragms 13 and 14, to an atmospheric exhaust passage containing a choke fitting 2, this communication being closed when the release valve |06 is seated. When the supply valve |05 is unseated communication is established from the pasage 23a to the passage I|3 to charge the chamber 93 with fluid under pressure from the control pipe 23, this communication being closed when the supply valve |05 is seated.

'I'he intermediate magnet valve device |02 is identical in construction to the high magnet valve device |0| and comprises a pair of oppositely seating valves, hereinafter called the supply valve ||5 and the release valve ||6, which are yieldingly urged into seated and unseated positions respectively by a spring |1 and actuated against the force ofthe spring i |1 into unseated and seated positions, respectively, upon energization of an electromagnet |8. With the release valve ||6 unseated, as shown, communication is established from a pasage ||4, connected to the chamber 94 between the diaphragms 14 and 15, to an atmospheric exhaust passage |2| containing a choke fitting |22, this communication being closed when the'release valve ||6 is seated.

With the supply valve I5 unseated, communication is established from the passage 23a to the passage ||4 leading to the chamber 94 so that the chamber 94 is thus charged to the pressure in the control pipe 23, this communication being closed when the supply valve ||5 is seated.

The low magnet valve device |03 comprises ,a double beat valve |26 which is urged to an upper seated position by a spring |21 and to a. lower seated position against the force of a spring |21 upon energization of an electromagnet |28. With the double beat valve |26 in its upper seated position, communication is established from the passage 23a to a passage |25 leading to the chamber 95 between the diaphragms'15'and 16, so that the chamber 95 is charged with fluid at the pressure established in the control pipe 23. With the double beat valve |26 in its lower seated position, communication through which the chamber 95 is charged is closed and another communication is established through which the passage |25 leading from the'chamber 95 is connected to an exhaust passage |31 containing a choke fitting |32, this exhaust communication being closed when `the double beat valve is in its upper seated position.

(b) Governor switch device 12 lIhe governor switch device |2 may be of any siutable construction and is illustrated diagrammatically'in simplified form as comprising a contact bridging member |35 carried in insulated relation on a stem |36 slidably mounted in a casing |46, a portion of which is shown, the member |35 being adapted to engage a pair of insulated resilient contact fingers |31 in circuitclosing relation. ,A biasing spring |38, interposed between a collar or flange |39 fixed on the stem |36 and a portion of the casing |46 yieldingly urges the stem |36 in a direction to eifectdisengagement of the contact bridging member |35 from the contact fingers |31. A centrifuge |4| urges the stemv |36 in the opposite direction, against the force of the spring |38, to eiect engagement of the contact bridging member |35 with the contact fingers |31. The centrifuge ili comprises a rotary element |62 which is suitably journaled in a portion of the casing |66 and rotated according to the speed of travel of the train as by a driving connection to a wheelaxle, such as the axle 6a, which driving connection is diagrammatically shown by the broken line. Two or more 'levers |63 carrying fly-balls |65 at the outer ends thereof are so mounted on the rotary element |62 that when the fly-balls |66 move outwardly under the iniiuence of centrifugal Jorce, the inner ends of the levers exert an upward force on the flange |39 oi the stem |36. The spring |36, the levers |63, and fly-balls |65 are so designed that upward movement of the stem |36, in opposition to the force of the spring |36, suiicient to cause engagement of the contact bridging .member |35 with the contact ngers i3? is not effected unless the speed of the train as reflected in the speed of rotation of the rotary element |62 exceeds a certain uniform or chosen speed, such as forty miles per hour.

` (c) Retardation controller device 13 The retardation controller device i3 may comprise a casing |66 having a chamber |69 containing an inertia element |5| in the form of a heavy weight, which is suitably mounted for v -horizontal movement in the casing, in a fric- |6| shifts toward the head end of the train, corresponding to the'left-hand direction in Fig. l,A against the force of a yielding spring |56. When the train is at rest or traveling at a substantially constant rate of speed, spring |56 urges the inertiaA element in the right-hand direction into contact with a stop lug |55 formed on or attached to the casing |68. The degree to which the inertia element |5| shifts in the left-hand direction away from the stop lug |55 increases in proportion to the increase in the rate of retardation of the train, the maximum movement of the inertia element |5| in the left-hand direction being .determined by a stop shoulder |56 on the casing which is engaged by the inertia element. f

A lever |56 is pivotally mounted on the casing |88 and extends through a slot or opening |58 in the wall of the casing |66. The inner end of the lever |66, within the chamber |66, carries a roller |66 andthe outer end of the lever has secured thereto, in insulated relation, a contact nger |62. in the normal position of the inertia brakes.

element |5|, the roller |59 is biased into contact with the left-hand edge of the inertia element by a lightly tensioned return spring |6| which is connected at one end to the casing |48' and at the opposite end to the inner end of the lever |56. Upon anapplication of the brakes, the shiftingl of the inertia element |'5| in the lefthand direction causes a counterclockwise rotation of the lever |56.

In its normal or vertical position, the contact finger |62 engages a stationary contact segment |63'. As the lever |56 is rotated in a counterclockwise direction, the contact finger |62 slides along the contact segment |63, disengages the segment |63, travels through a predetermined arc and then engages another contact segment |66. The spring |54 may be suitably designed and tensioned, and the segments |63 and |615 may be so arranged and disposed as to cause the Contact finger |62 to disengage the segment |63 when the rate of retardation of the train exceeds a certain uniform rate, such as two miles per hour per second, and so that the contact finger |62 does not engage the contact segment |66 unless the rate of retardation of the train exceeds another higher certain uniform rate of retardation, such as three miles per hour per second. For simplicity, the range of retardation rates over which the contact nger |62..engages the contact segment |63 will hereinafter be termed range A of retardation rates, the range of retardation rates over which the contact finger |62 engages neither the segment |63 nor the segment |64 will b e termed range B, and the range of retardation rates over which the contact `finger |62 engages the contact segment |66 will be termed range C.

Suitable means is providedfor increasing the initial tension of the springl so as to necessitate a higher rate of retardation of the train to produce a Agiven degree of movement of the contact finger |62 from its normal position and thus correspondingly affect the ranges A, B, and C of retardation rates. For example, a mechanism such as is described and claimed in the copending application of Ellis E. Hewitt, now Patent 2,147,- 295 and assigned to the assignee of the present application, may be provided. As shown in Fig, 1, such mechanism may comprise a piston |61 which is subject on one side to the pressure of fluid in a chamber |66 constantly connected to the brake pipe 26 by a branch pipe 26a., and subject on the opposite side to the opposing pressure of a spring |69. The piston |61 has a stem |1| which-is pivotally connected to one end of a lever |12, the opposite end of which has pivotally connected thereto a stem |14 carrying thereon in fixed relation a collar or ange against which the spring |56 presses.` The lever |12 is pivoted intermediate the ends thereof, as on a pin |13 carried by the casing |48, and when the pressure in the chamber |66 exceeds a certain predetermined pressure sufficient to overcome the spring |63 and shift the piston in the right-hand direction into engagement with a stop-shoulder |16 formed on the casing, the iiange |15 is positioned as shown to determine the initial tension of the spring |56 for service applications of the When a suiicient reduction in the pressure of the fiuid inthe chamber |66 from the normal brake pipe pressure carried therein is effected, as in the case of emergency applications of the brakes, the spring |69 acts to shift the piston |61 in the left-hand direction until the piston strikes the cap or cover |18 closingthe open end of the chamber |68, the stop ange |15 being correspondingly shifted in the right-hand direction to increase the initial tension of the spring |54.

It will accordingly be readily apparent that by suitably selecting the length of the lever |12 and the pivotal point of pin |13 intermediate the ends of lever |12, any desired degree of increase in the initial tension of the spring |54 as between service applications and emergency applications of the brakes may be effected whereby the ranges A, B and C of retardation rates may be correspondingly varied. For example, instead of the previously given limits for ranges A, B and C, the range A for emergency application of the brakes may cover from zero to three miles per hour per second, range B may cover from three 'to four and one-half miles per hour per second, and range C may cover retardation rates in excess of four and one-nalil miles per hour per second.

(d) Automatic valve device 14 device 21 and which is eiective upon an increase in brake pipe pressure to release iiuid under pressure from the pipe ISI and to eiTect charging oi' the auxiliary reservoir 2| from the brake pipe 24.

(e) Brake valve device 15 The brake valve device I may be of any suitable construction and for purposesvof the present application there is illustratively employed a brake valve device of the type described and claimed in the copending application Serial No. 105,659, of Ellis E. Hewitt, led October 15, 1936, and assigned to the assignee of the present application. It is deemed unnecessary for purposes of the present application to describe the brake valve deviceI I5 in detail, it being necessary to understand merely that -the single handle |83 of the brake valve d evice is operative over the same zone or range of movement in a. horizontal plane to effect straight-air applications of the brakes or automatic applications of the brakes, depending upon whether a manually operative selector element |84 is vpositioned in a straight-airA application position or an automatic application position.

With the selector element |84 in straight-air position, the shitting of the operating handle I 83 of the brake valve device I5 from its normal release position into the application zone, causes fluid under pressure to be supplied from the pipe 25, leading from the feed valve device 25 and hereinafter termed feed valve pipe 25, to a pipe |85 leading to the side of the double check valve 21 opposite to that to which the pipe |8| from the automatic valve device I4 is connected. The brake valve device I5 includes a .self-lapping valve 'i mechanism effective for straight-air operations,

and thus the pressure attained in the pipe |85 is in proportion to the degree of movement of the operating handlel |83 outfof its normal release position into the application zone. The construction oi the brake valve device I5 is such that when the handle |83 reaches the full service pition thereof, a maximum pressure is attained in the pipe |85, and evenl though the operating handle |83 is shifted beyond the full service position to an emergency position, no further increase in the pressure in the pipe |85 occurs beyond the maximum pressure for a full service application of the brakes.

With the operating handle |83 of the brake valve device I5 in its normal release position, and with the selector element |84 'in either the straight-air position or automatic position, the pipe |85 is vented to atmosphere and the brake pipe 24 is charged with iluid under pressure from the feed valve pipe 26. During straight-air operation of the brake valve device I5, connections are maintained through the brake valve device so that the brake pipe 24 remains charged to the normal 'handle |83 to emergency position while the selector element |84 is in automatic position, causes reduction in brake pipe pressure at an emergency rate and at the same time causes fluid under pressure to be supplied from the feed valve pipe 25 to the pipe |85 to the maximum degree of pressure attainable therein, that is, to the degree of pressure corresponding to a full service application of the brakes.

The double check valve device 21 is of standard construction and includes a shiftable piston valve, not shown, which is subject on one side to `the pressure in the pipe |8| and on the opposite side to the pressure in the pipe |85 and which is effective to establish connection between either the pipe I8I or the pipe |85 and the control pipe 23, depending upon the relation of the pressure in the two pipes |8| and |85.

As will be hereinafter explained, the maximum pressure established in the pipe I8| for emergency applications of the brakes exceeds the maximum pressure established in the pipe |85 for straight-air applications of the brakes and thus, 4although both pipes |8| and |85 are simultaneously supplied with fluid under pressure, 'the pressure in'the pipe |8| predominates and thus causes the double check valve device 21 to be conditioned to establish communication from the pipe |8| to the control pipe 23.

(f) Additional equipment and control circuits The fluid pressure operated switch device I1 may be of any suitable construction andy may comprise a casing containing a piston`|9| subject on one side to :duid under pressure in a chamber |32 connected by a branch pipe |93 to the control pipe 23. When the pressure of the fluid supplied to the control pipe 23 and acting in the chamber |52 on the one side of the piston I9| exceeds a predetermined low pressure, such as one or two pounds per square inch, the piston ISI is moved against the force of a spring |94, which yieldingly opposes movement of the piston. The piston has a stem |85 carrying, in insulated relation thereon, a contact membet'l. The contact member |35 engages a.V lower contact member |31 when the pressure in the control pipe 23 and chamber |82 is less than the predetermined pressure of one or two pounds per square inch, and is shifted out of engagement with the contact member |31 and into engagement with -an upper contact member |88 when the pressure of the uid in the control pipe and chamber |92 exceeds the predetermined pressure.

The electrical relays 35, 3, 3l and 39 are of any suitable standard construction comprising an electromagnet an associated staftionary magnetic core, and a movable armature actuated upon energization of the electromagnet. For simplicity of description, the electrical relays will be described as having front-contact members" and back-contact members, and it will be understood that, as employed herein, the term front-contact member designates a contact member which is actuated from a circuit-opening to a circuit-closing position when the electromagnet of the relay is energized, and the term back-contact member designates a contact member which is actuated from. a circuit-closing position to a circuit-opening position when the v relay electromagnet is energized. The relay 35 is illustrated diagrammatically as comprising an electromagnet 2M and a pair of front-contact members 202 and 263.

The relay 3d may comprise an electromagnet 264i and a pair of front-contact members 225 and 206.

The relay 3l may comprise an electromagnet 2d?, a back-contact member 2632, and a irontcontact member 2%.

' The relay 32 may comprise an. electromagnet 2li, two front-contact members 282 and 2id, respectively, and a back-contact member 2id.

The diderential relay E33 may comprise two separate electromagnet coils 2|@ and 2H., connected respectively to the terminals of the generators #lli and i5 as shown, a back-contact member 2id and a iront-contact member 2id. The electromagnet coils 2id and 2li or the relay i3 are so connected to the generators 636i and t5 that the direction of current flow in the two windings is in opposite directions whereby the magnetic flux set up by energization of the two eiectromagnet coils is in opposite directions. The two generators 44 and t5 have substantially identical speed-voltage characteristics and, consequently, if the wheels t associated with the more heavily braked axle 9 and the wheels'ta associated with the less heavily braked axle @a rotate at the same speed, the resultant magnetic ux produced in the magnetic core associated with the electro. magnet'coils 2id, 2|'| of the relay 33 is substantially zero and as a result the back-contact member 2|8 and the front-contact member 2|@ are normally in circuit-closing and circuit-opening positions, respectively. Ii, due to the heavier braking force exerted on the wheels t and axle 9, slipping of the wheels t is initiated while the wheels 3a, continue to rotate at a speed corre sponding to the speed of travel of the train, the current supplied from generator @d to the electromagnet Winding 2|@ reduces rapidly from a value corresponding to the current supplied from the generator 45 to the electromagnet winding 2|l on account of the decrease in voltage generated by the generator ed at a decreased speed. Upon a suicient reduction in the rotational speed of the wheels 8 and axle a during the slipping interval,

the 'resultant magnetic ux produced in the niagl netic core associated with the electromagnet coils 2|B and 2H is in a direction to cause shifting of the back-contact member 2id and front-contact member 2|9 to circuit-opening and circuit-closing positions, respectively.

The magnet valve device d6 may comprise a donne beat valve 22| which is yleiaingiy urged' into an upper seatedposrtion by a spring 2 22 and chamber 224 to a chamber 225 which is connected to another portion of the pipe Si leading to the chamber 59 of the valve mechanism Brake cylinder ita is connected by a branch pipe Sla to the portion of the pipe 5| leading from the magnet valve device 45 to the valve mechanism il. Thus, with'the double beat valve 22| in its upper seated position, fluid under pressure supplied into the pipe 6| from chamber 59 of the valve mechanism ows to the brake cylinder iii and the brake cylinder lila,

When the double beat valve 22| is in its lower seated position, communication between the chambers 225 and 22d is cut-o and communication is opened from the chamber 22d to a chamber. 226 which is constantly open to atmosphere through an exhaust port 22'i. Thus fluid under pressureis released to atmosphere solely from the brake cylinder id.

One of the terminals of the battery iii, hereinafter referred to as the positive terminal,.is connected to the contact member it@ o the pressure switch |l by a wire 23|, and the opposite terminal of the battery it, hereinafter called the negative terminal, is connected to ground. The contact member itl of the pressure switch il is connected to the back-contact member 2|?,l

' of the dierentiai relay i3 by a wire 232, and the back-contact member 2id, in the circuit-closing 233 to which one terminal of the eiectromagnet 2ii| of relay 35 is connected. The opposite terminal of the electromagnet Zi of relay 35 is connected to the negative terminal of the battery it, as through a ground connection including a wire 23d connecting the opposite terminal to ground. With the contact member it@ ci the pressure switch il in engagement with the contact member |9l, and with the back-contact member 2id of differential relay d3 in circuit-closing position, it will thus be apparent that a circuit is completed forenergizing the electromagnet 2d@ of the relay 35 so that the front-contact members 2M and 203 of the relay 35 are actuated to circuit-closing position.

'The contact member 22 of the relay 35 is connected by a branch wire 235, a wire 23d and wire 23| to the positive terminal of the battery i8 and, in the circuit-closing position thereof connects branch wire 235ma wire 23"? which is connected to the wire 232. Thus with the frontcontact member 202 of relay 35 in circuit-closing position, a holding circuit is established for maintaining the electromagnet 20| of relay 35 energized independently of the separation of the contact member |36 of pressure switch Il from the contact member |91. *l

The front-contact member 249 of the diie'rential relay d3 is connected by a wire 239, wires 23B and 23| to the positive terminal of the battery i3. and -when. in circuit-closing position,

connects the wire `239 to a wire 24| which is connected to one terminal of the electromagnet 223 of the magnet valve device I6 and to one terminal of the electromagnet 223 and the opposite terminal of the signal lamp 41 are respectively connected to the negative terminal of battery I8 as by connections to ground in the man-l ner shown. It will thus be seen that Whenever the contact member 2|8 of relay 43 is in circuitclosing position the electromagnet 223 of the magnet valve device 246 is energized and the signal lamp 41 is illuminated.

The contact member |98 of the pressure switch I1 is connectedby a branch wire l243 and a wire 244 including a flexible portion, to *thev Contact finger |62 of the retardation controller I3.v The contact segment |63, associated with the contact nger I 62, has a Wire 245 connected theretowhich, in the circuit-closing position of the contact member 203 of the relay 35, is connected to a Wire 246 to which one terminal of the electromagnet 204 of relay 36 is connected. The opposite terminal of the electromagnet 204 is connected to the negative terminal of the battery i8 by a branch wire 241, wire 234, and through ground.

It will thus be seen that with the contact member |96 of the pressure switch |1 engaging the contact member |08, with the contact linger |62 of the retardation controller engaging the contact segment' |63, and with the front-contact member 203 of the relay 35 in circuit-closing position, the electromagnet 204 of relay 36 is energized.

One terminal of the electromagnet 201 of the relay 31 is connected by a wire 249 to the contact segment |64 of the retardation controller I3 and the other terminal is connected to the negative terminal of the battery I8 through a ground connection including a branch wire 25| and the wire 234. Thus, with the contact member |86 of the pressure switch I1 engaging the contact member |08 and with the contact finger |62 of the retardation controller I3 engaging the conl tact segment |64, electromagnet 201 of relay 31 is energized.

One of the contact lfingers |31 of the governor switch I2 has the Wire 244 connected thereto and the other contact finger |31 is connected by a wire 252 to one terminal of the electromagnet v 2I| of the relay 38.- The other terminal of the clectromagnet 2|I of relay 38 is connected to the negative terminal of the battery I8 as through a ground connection including a branch wire 253 and wire 234. Thus, with the contact member |96 of pressure switch I1 engaging contact member |38 and with the contact member |35 of the governor switch in circuit-closing engagement with the contact ngers |31, electromagnet 2|| of relay 38 is energized.

Front-contact member 205 of relay 36 is constantly connected to the positive terminal of battery I8 through a branch Wire 254, wires 235, 236 and 23| and in the circuit-closing position thereof connects the wire 254 to a Wire 255' which is connected to the front-contact member 2I2 of the relay 38. Contact member 2| 2 of relay 38, when in circuit-closing position, connects the wire 255 to the high train wire 3|. One terminal o! the electromagnet |08 of the magnet valve device I of the valve mechanism II is connected by a branch wire 26| to the high Wire 3|, the opposite terminal of the electromagnet being connected to the negative terminal of the battery I8 as through a ground connection in the manner shown. Thus, with the front-contact members 205 and 2I2 of the relays 36 and 38 respectively in circuit-closing positions, electro- 'l magnet |03 vof the magnet valve device |0I is energized.

Back-contact member 208 of relay 31 is constantly connected to the positive terminal of the battery I8 by a wire 264, Wires 235, 236 and 23| and in the circuit-closing position thereof connects the wire 264 to a wire 265 to which the front-contact member 2|3 of the relay 38 is connected. When the front-contact member 2|3 of the relay,38 is in circuit-closing position, it connects the wire 265 to the intermediate train wire 32. One terminal of the electromagnet |I8 of the magnet valve device |02 of, the valve mechanism |I is connected to the intermediate train wire 32 by a branch wire 262, the other terminal being connected to the negative terminal of the battery I8, as through a ground connection in the manner shown. Thus, with the back-contact member 208 of relay 31 and frontcontact member 2| 3 of relay 38 both in circuitclosing position, the electromagnet ||8 of the magnet valve device |02 is energized.

Front-contact member 206 of relay 36 is connected to the intermediate train Wire 32 by a wire 266 and in a circuit-closing position thereof connects the wire 266 to a wire 261 to which the back-contact member 2|4 of the relay 38 is connected. In the circuit-closing position thereof, back-contact member 2|4 of relay 38 connects wire 261 to the wire 236 and thus to the positive terminal of the battery I8. Accordingly, it will be seen that with the front-contact member 206 of relay 36 in circuit-closing position and with the back-contact member 2| 4 of relay 38 in circuit-closing position, electromagnet ||8 of the magnet valve device |02 is energized independently of the circuit through back-contact member 208 of relay 21 and front-contact member 2|3 of. relay 38.

Front-contact member 209 oi' the relay 31 is connected by a branch wire 268 to the wire 261 and in the-circuit-closing position thereof connects the wire 268 to the low train wire 33. One lterminal of the electromagnet |28 of the magnet valve device |03 of the valve mechanism is connected to the train wire 33 by a branch wire 263, the other terminal being connected to the negative terminal of the 'battery |8 as through a ground connection in the manner shown. Thus, with the front-contact member 208 of relay `31 and back-contact member 2|4 of relay 38 both in circuit-closing position, the electromagnet |28 of the magnet valve device |03 is energized.

-Or'lrlza'rron or EQUIPMENT SHOWN 1N F1o. 1. (a) Running condition With the car or train running under power or coasting, with the handle |83 of the brake valve device I in the release position thereof, with the selector element |84 in either straight-air or automatic positions, and with the main reservoir I9 fully charged with uid under pressure in the usual manner, fluid under pressure is supplied to the main reservoir pipe 22 and to the feed-valve pipe 26. As will appear hereinafter, with the brake valve handle I 83 in release position, the supply valve 58 and the release valve 62 of the valve mechanism are respectively in seated and unseated positions and, accordingly, the chamber 56 containing the supply valve 58 is charged with fiuid under pressure from the .main reservoir I8 throughv the main reservoir pipe 22 andbranch pipe 51 while brake cylinders I0 and |0a are vented to atmosphere by way of Pipe and passage 6I, chamber 53 of valve mech- 1I anism II past the unseated release valve 62 and exhaust port 63 so that the brakes associated with the wheels fixed to the axles 9 and 9a are all released. Under the conditions assumed, front-contact member 2I9 of the differential relay 43 is in circuit-opening position and, consequently, the electromagnet 223 of the magnet valve device 46 is deenergized so that the brake cylinder I 0 is connected through the magnet valve device 46 to the chamber 59 of the valve mechanism Il.

With the handle |83 of the brake valve device I5 in release position, connections are established through the brake valve device whereby fluid under pressure is supplied from the feedvalve pipe 26 into the brake pipe 24 so that it is accordingly charged with fiuid under pressure as regulated by the feed valve 25.

From the brake pipe 24 fluid under pressure flows to the automatic valve device I4 where it acts on the operating piston thereof to condition the automatic valve device to establish communications through which the auxiliary reservoir 2| is charged with fluid under pressure from the brake pipe 24 and the pipe I8I is vented to atmosphere.

A Brake pipe pressure acting in chamber |68 of.

retardation controller I3 shifts the piston A|67 against the opposing force of the spring |69 into engagement with the stop shoulder |16 so that the stop flange |15 ris positioned to initially tension the spring I5@ of the retardation controller for service applications of the brakes.

In order to obtain some idea as to the relative fluid pressures in the various pipes and other parts of the equipment, let it be assumed that the main reservoir i9 is maintained charged to a pressure of one hundred and twenty-five poundsper square inch, that the feed-valve 25 regulates the pressure supplied to the feed-valve pipe 23 an thus the pressure in the brake pipe 24 to a pressure of one hundred and ten pounds per square inch, that the maximum pressure which may be established in the pipe |85 and thus in the control pipe 23 for straight-air applications is seventy-five pounds per sq. in., that the maximum pressure which is established in the control pipe 23 for automatic service applications of the brakes is seventy-five pounds per sq. in., and that the maximum pressure established in the control pipe 23 for emergency applications of the brakes, that is the pressure of equalization between the auxiliary reservoir 2| and the control pipe 23, is one hundred pounds per sq. in.

(b) Application of the brakes initiated at train speeds in excess of a certain uniform speed I given in the copending application of George W.

Baughman, Serial No. 126,375, filed February 18, 1937, and assigned to the assignee of the present application. For further simplicity, it will be assumed that a certain fluid pressure, such as seventy-flve' pounds per sq. in., is established in the control pipe 23 to initiate the application of the brakes, and that unless otherwise specified, the pressure in the control pipe remains unchanged.

Let it now be assumed that an application of the brakes is initiated when the train is traveling at a speed of one hundred miles per hour, the governor switch device I2 being correspondingly in circuit-closing position and the relay 38 energized upon the shifting of the contact member |96 of the pressure switch Il into contact with the contact member |98. As previously pointed out, the relay 35 is maintained energized, over a holding circuit including its own front-contact member 202, independently of the separation of the contact member |90 of the pressure switch I1 from the contact member |91.

In view of the fact that the Contact finger |02 of the retardation controller I3 engages the contact segment |63 at the time the application of the brakes is initiated, the engagement of the contact member |95 with the contact member |98 of the pressure switch I'I completes the circuit previously described for energizing the electromagnet 203 of the relay 30.

With the electromagnets of the relays 30 and 38 energized and the electromagnet of the relay 31 deenergized, the circuits, previously described, for energizing the electromagnets M38 and H0 of the magnet valve devices I9| and |02, respectively, are completed.

Accordingly, fluid under pressure is supplied from the control'pipe 23 and branch pipe and passage 23a to the diaphragm chambers 93, 94 and 95- under the control of the magnet valve devices IllI,I02'and |03, respectively. Chamber 93 at the right of the smallest diaphragm lt, being directly connected to the passage 23a is likewise simultaneously charged to the pressure established in the control pipe 23.

Accordingly, it will be seen that the fluid pressure forces exerted on opposite sides of the diaphragms lli, I5 and 16 are balanced, only the largest diaphragm I3 having an unbalanced fluid pressure force acting thereon in the chamber 93. Thus the diaphragm 73 is flexed and the slidable member 66 shifted in the left-hand direction to effect operation of the release valve 02 and the supply valve 58, in the manner previously described, to supply fluid under pressure from the main reservoir pipe 22 to the brake cylinders I0 and I0a.

The pressure of the fluid supplied to the brake cylinders I0 and AIlla acts in the chamber 59 on the left-hand face `of the follower disc 'l associated with the largest diaphragm 'i3 and, when the force of the fluid pressure in the chamber 59 substantially balances the opposing force of the fluid pressure in the chamber 93, spring 'II becomes effective to shift the slidable member 66 sufficiently in the right-hand direction to operate the supply and release valves 58 and 62 to lap or close both the supply and the release communications so that the pressure established in lease valve 62 or in the event of reduction of the pressure in the brake cylinders for any other reason, the higher unbalanced pressure main- 1v1/mms sr-emmene,

tained in the chamber 83 again becomes ef- ,fective to cause unseating of the supply valve 58 to replenish the supply of fluid under pressure to the brake cylinders from the main reservoir pipe 22. Upon the restoration of the pressure in the brake cylinders to a pressure corresponding to the pressure in the control pipe 23, the supply valve 58 is again seated. It will thus be seen that the valve mechanism II operates to maintain the pressure in the brake cylinders against leakage.

As the train speed reduces from the initial high speed of one hundred miles per hour, the contact finger |62 of the retardation controller I3 is gradually shifted in a counterclockwise direction because of the increase in the rate of retardation with the reduction in speed. When the contact finger |62 leaves the range A of retardation rates, that is, disengages from contact segment |63, and enters the range B of retardation rates, the circuit previously described whereby the electromagnet of the relay 36 is energized, is interrupted and the contact members 205 and 206 of relay 36 shifted to circuit-opening position. Assuming that the speed of the train is still in excess of the certain uniform speed of forty miles per hour and that the governor switch device I2 is accordingly in circuit-closing position to maintain the electromagnet of the relay 38 energized, it will be seen that electromagnet I I8 of the magnet valve device |02 is maintained energized through a circuit including the back-contact member 208 of relay 31 and front-contact member 2I3 of the relay 38, independently of the operation of the front-contact member 206 of relay 36 to circuit-opening position, but that electromagnet |08 of the magnet valve device |0I is deenergized because the circuit therefor is interrupted due to the shifting of the contact member 205 of relay 36 into circuit-opening position. As in the previous instance, the electromagnet |28 of the magnet valve device |03 is deenergized because the front-contact member 209 of the relay 31 is in circuit-opening position.

As a result ofthe deenergization of the electromagnet |08 thereof, the magnet valve device IOI is actuated to cut off the supply of fluid under pressure to the diaphragm chamber 83 and to release fluid under pressure therefrom through the choke fitting II2. The restricted passage in the choke fitting II2 may be any desired size so that the rate of release of fluid under pressure from the chamber 93 may be. timed to a desired rate. Obviously, upon the release of fluid under pressure from the chamber 83, the force acting on the largest diaphragm 13 and urging the slidable member 66 in the left-hand direction is diminished, so that the higher brake cylinder pressure in the chamber 59 tends to shift the diaphragm 13 in the right-hand direction. At the same time the reduction of the pressure in the chamber 93 causes a differential fluid pressure force to be exerted in the lefthand direction on the diaphragm 14. However, the differential fluid pressure force on the diaphragm 13 is larger than the differential fluid pressure force on the diaphragm 14 and consequently as the pressure in the chamber 93 reduces, the spring 1| becomes effective to unseat the release valve 62 and thus effect the release of fluid under pressure from the brake cylinders I0 and |0a, the rate of reduction of pressure in the brake cylinders I0 and I0a being determined according to the rate of reduction of the pressure in diaphragm chamber 93.

vvv Ilvlu ullvu When the fluid under pressure in chamber 93 has been completely vented to atmosphere, the pressure in the brake cylinders |0 and |011V will obviously be determined according to the force exerted by the uid under pressure in the chamber 94 on the diaphragm 14 and urging the slidable member 66 in the left-hand direction. Obviously, since brake cylinder pressure always acts on the follower disc 18 having an area corresponding to the effective area of the largest diaphragm 13 to oppose any force in the opposite direction, it will be seen that the pressure in the brake cylinders is reduced, upon the deenergization of the electromagnet I 08 of the magnet valve device IUI, to a pressure which bears a certain uniform ratio to the pressure established in the control pipe, which ratio is substantially the ratio of the effective area of the diaphragm 14 to the effective area of the diaphragm 13.

'I'he diaphragms 13, 14, 15 and 16 may, of course, be of any desired area and relative areas, but for simplicity let it be assumed that the areas of the diaphragms 13, 14, 15 and I6 are l, 3A, 1/2, and 1/3 units of area respectively. Assuming then that the area of the diaphragm 14 is threefourths of the area of the diaphragm 13, the pressure established in the brake cylinders I0 and I0a, upon the deenergization of the electromagnet |08 of the magnet valve device |0I in the manner just described, is in ratio to the pressure established in the control pipe 23 as three is to four. With seventy-five pounds sq. in. pressure established in the control pipe 23, the brake cylinder pressure is reduced to approximately 56 pounds per sq. in.

Now let it be assumed that with the train speed still remaining above the certain uniform speed of forty miles per hour and notwithstanding the reduction in brake cylinder pressure as just described, the further reduction of speed of the train causes an increase in the rate of retardation of the train such that the contact finger |62 of the retardation controller I3 is shifted out of the range B of retardation rate and into the range C, wherein the contact linger engages contact segment |64.'

The engagement of the contact finger |62 with the contact segment |64 of the retardation controller establishes a circuit, previously described. for energizing the electromagnet of the relay 31. Consequently, the back-contact member 208 and front-contact member 200 of the .relay 31 are shifted to circuit-opening and circuit-closing positions, respectively. l

The electromagnet |I8 of the magnet valve device |02 is accordingly deenergized due to the interruption of the circuit thereof by shifting of the back-contact member 208 of relay 31 to circuit-opening position. The shifting of the front-contact member 208 of relay 31 to circuitclosing position is without effect at this time since the back-contact member 2I4 of the relay 38 is still held in circuit-opening position, relay 38 remaining energized for train speeds in excess of the certain uniform speed.

It Will thus be seen that where previously the electromagnet I I8 of the magnet valve device |02 was energized, now the electromagnets of all of the magnet valve devices IOI, |02 and |03 are deenergized. As a result of the deenergization of the electromagnet of the magnet valve device |02, communication for the supply of fluid under pressure to the diaphragm chamber 94 is closed and the exhaust communication through the choke fitting |22 is opened, thereby effecting the release of fluid under pressure from the chamber 94 at a rate determined by the size of the restricted passage in choke fitting |2`2. As in the case of the reduction of fluid under pressure in the chamber 93, reduction of the pressure of uid in the chamber 94 results in reduction of the pressure of fluid in the brake cylinders I0 and |0a at a rate determined according to the rate of reduction of the fluid under pressure in the chamber 94.

When the fluid under pressure in the chamber 94 is reduced to atmospheric pressure, the pressure established in the brake cylinders I0 and I 0a is in substantially the same ratio to the pressure established in the control pipe 23 as the effective area of the diaphragm 15 is to the effective area of the diaphragm 13, that is on the basis of the assumed areas of the diaphragms, in the ratio of one to two. With a pressure of seventy-five pounds per sq. in. established in the control pipe 23, the pressure established in the brake cylinders I0 and Illa at this stage of the operation is accordingly approximately thirtyseven and one-half pounds per sq. in.

Let it now be assumed that with the brake control equipment conditioned as just described, that is, With the contact finger |62 of the retardation controller I3 in engagement with the contact segment |64 and a pressure established in the brake cylinder which has a one-to-two ratio to the pressure established in the control pipe 23, the speed of the train reduces below the certain uniform speed of forty miles per hour so that the governorI switch device I2 is shifted to circuitopening position to cause deenergization of the electromagnet 2II of the relay 38. The consequent shifting of the back-contact member 2I4 of relay 38 to circuit-closing position, completes the circuit previously described for energizing the electromagnet |28 of the magnet valve device |03, energization of Which results in the closing of the supply communication to the 'chamber 95 and the opening of an exhaust communication for releasing fluid under pressure from the chamber through the choke fitting |32.

Keeping in mind that the chambers 93 and 94 have been previously reduced to atmospheric pressure. the reduction of the pressure in the chamber 95 results in the reduction of the pressure in the brake cylinders I0 and I0a at a rate determined by the rate of reduction in pressure in the chamber 95, in a manner similar to that described With respect to the reduction of pressure in the chamber 93.

When the pressure of the fluid in the chamber 95 is reduced to atmospheric pressure, the corresponding pressure established in the brake cylinders I0 and I0a is in ratio to the pressure established in the control pipe 23 as the effective area of the diaphragm 16 is to the effective area of the diaphragm 13. Such ratio being assumed to be a one-to-three ratio, the pressure established in the brake cylinders I0 and I0a for a control pipe pressure of seventy-five pounds per sq. in. is twenty-five pounds per sq. in.

Let it now be assumed that the reduction of brake cylinder pressure just effectedis such as to reduce the rate of retardation of the car or train sufficiently that the Contact nger |62 of the retardation controller I3 recedes toward its normal position out of range C into the rang B,

thereby disengaging contact segment |64. Dis,

engagement of the contact nger |62 from the contact segment |64 interrupts the circuit previously described for energizing the electromagnet of the relay 31. Electromagnet |28 of magnet valve device |03 is accordingly deenergized due to the interruption of the energizing circuit therefor by the shifting of the front-contact member 209 of the relay 31 to circuit-opening position. The shifting of the back-contact member 208 of the relay 31 to circuit-closing position is ineffective to cause energization of the electromagnet I I8 of the magnet valve device |02 due to the fact that the front-contact member 2| 3 of the speed relay 38 is in circuit-opening position.

It Will thus be seen that the electromagnets of the magnet valve devices IOI, |02 and |03 of the valve mechanism I I are again all deenergized simultaneously so that the diaphragm chambers 93, 94 are at atmospheric pressure and the chambers 95 and 96 are charged to the pressure established in the control pipe 23. Accordingly, it Will be seen that the valve mechanism II is operated to resupply fluid under pressure to the brake cylinders I0 and I 0a to build up the pressure therein to a pressure having a one-to-two ratio to the pressure established in the control pipe, or approximately thirty-seven and one-half pounds per sq. in.

Should the contact linger |62 of the retardation controller I3 recede suiiiciently toward its normal position as to enter the range A and thereby engage the Contact segment |63, a further increase in brake cylinder pressure is effected. It Will be seen that such is the case because the engagement of the Contact finger I 62 with the contact segment |63 of the retardation controller completes a. lcircuit, previously described, for energizing the electromagnet of the relay 36, thus causing the circuit for energizing the electromagnet I I8 of the magnet valve device |02 to be completed through the back-contact member 2I4 of the relay 38 and the front-contact member 206 of relay 36. The circuit for energizing the electromagnet of the magnet Valve device |0| is not completed despite the shifting of the front-contact member 205 of relay 36 to circuit-closing position, because the front-contact member 2I2 of the relay 38 remains in circuit-opening position. Thus, with only the electromagnet I I 8 of the magnet valve device |02 energized, diaphragm chambers 94, 95 and 96 are charged to the pressure established in the control pipe 23, while only the chamber 93 is at atmospheric pressure. Accordingly, an increase in pressure in the brake cylinder pressure is effected to the degree that the pressure in the brake cylinders bears a three-tofour ratio to the pressure established in the control pipe 23, or approximately fifty-six pounds per sq. in.

If as the speed of the train further reduces, the rate of retardation increases suiciently, so thatl the contact nger |62 of the retardation controller again leaves the range A of retardation rates and enters either of the other ranges B or C of rates of retardation, brake cylinder pressures corresponding thereto and previously described are established in the manner previously described.

When the car or train is brought to a complete stop, the contact linger |62 of the retardation controller automatically returns to its normal position in engagement with the contact nger |63 and thus the pressure established in the brake cylinders to hold the car or train at a standstill will bear a three-to-four ratio to the pressure established in the control pipe 23, or approximately fifty-six pounds per sq. in.

(c) Applications of the brakes initiated at train speeds below the certain uniform speed If an application of the brakes is initiated at a time that the train is traveling at a speed below the certain uniform speed of forty miles per hour so that the governor switch I2 is in circuit-opening position and the relay 38 controlled thereby is accordingly deenergized, it will be seen that the maximum brake cylinder pressure established.

will bear a three-to-foiir ratio to the pressure established in the control pipe, as compared to the maximumor one-to-one ratio established in the case of an application of the brakesinitlated at a time that the train was traveling at a speed in excess of the 'certain uniform speed.

It will be apparent that such is the case for with the contact finger |62 in engagement with the contact segment |63 of the retardation controller I3 and with the electromagnet of the relay 36 accordingly energized, only the electromagnet ||8 of thel magnet valve device |02 is energized, the energizing circuit including the backcontact member 2|4 of the relay 38 and the frontcontact member 206 of the relay 36. The electromagnet |08 of the 'magnet valve device |0| is not energized, despite the shifting of the frontcontact member 205 `oi relay 36 to circuit-closing position, because the front-contact member 2| 2 of the relay 38'is in circuit-opening position.'

Electromagnet |28 of the magnet valve device |03 is not energized because electromagnet 201 of the relay 31 is deenergized and, consequently, the front-contact member 209 of the relay 31 is .in circuit-opening position to interrupt the circuit for energizing the electromagnet of the magnet.

valve device |03. l

As in the case of the deceleration of the train from a speedin excess of the certain uniform speed of forty miles per hour, after havingl been reduced to speeds below forty miles per hour, the

ratio between the pressure established in the' brake cylinders |0and |0a and the pressure established in the control pipe 23 is determined according to the position of the Contact nger |62 of the retardation controller I3 in range A, range B or range C of retardation rates. Thus, as the speed of the train reduces following'an application of the brakes initiated atfthe time the train is traveling at a speed below forty miles per hour, valve mechanisml is automatically controlled to vary the ratio between the brake cylinder pressure and the pressure vestablished in the con--v trol pipe according to the retardation of the train being within range A, range B or range C of retardation rates.

(d) Release of the brakes.

'Ihe brakes may be released at any time-by 11educing the pressure in the control pipe 23 to 'at'- mospheric pressure, In such case, with all of they the release valve 62 to completely release iluid under pressure from the brake -cylinder's I0 and |0a, the valve mechanism Il thus being returned to the vposition shown in Fig. 1. l

Upon the reduction of the pressure in the control pipe 23 to atmospheric pressure, the pressureswitch |1 is operated s'o that the .contact member |96 is shifted out of contact with contact inger |98 and into contact with the contact nger |91. Thus the electromagnet of relay 36 veven though the magnet valve devices .|0|, |02

and |03 are conditioned to supply fluid under pressure to the diaphragm chambers 93, 94 and 85, reduction of pressure in the control pipe 23 causes the higher pressure previously established in the chambers 93, 94 and 95 to respectively unseat the check valves and thus effect equalization of the pressure in the diaphragm chambers with the pressurein the control pipe. It will be apparent that the check valves 93a, 94a and 95a function at any time during an application o1' the brakes to vary the pressure in the diaphragm chambers 93, 94 and 95 in accordance with a variation in the pressure in the control pipe 23 so as to correspondingly vary the pressure in the brake' cylinders |0 and |0a, without, however,

causing variation of the particular ratio in effect at the time between the pressure in the brake cylinder and the pressure in the control pipe' 23.

If the car or`train is withdrawn from service, obviously .it is not desirable that the wheel slip relay 35 be permitted to continue inthe energized condition overthe holding circuit previously described. Accordingly a suitable switch (not shown) may be provided for effecting deenergization of the electromagnet of the wheel-slip relay 35 when the car or train is not in operation.

of the brakes initiated at a time that the train speed is in excess of a certain .uniform speed lAs thus iar described, it has been assumed, for simplicity, that the application of the brakes was not attended by a slipping or a sliding of any of the wheels of the car or train, and in such respect, the operation of the equipment shown in Fig 1 is substantially identical to that described for the embodiment shown in Fig. l of the Patent 2,096,505 of George W. Baughman, above referred to.

According to our invention, however, additional equipment is included in the embodiment shown in Fig. 1V of the present `application for guiding against sliding of the car wheels.

Let it, therefore, now be assumed that the initial pressure established in the brake cylinder |0 upon the initiation of an application of the brakes when the train is traveling at a speed, such as one hundred miles per hour, causes the wheels 8 associated with the more heavily braked axle l to begin to slip, that isreduce in speed from a. ro-

tational speed corresponding to the speed of travel of the train to a zero rotational speed correspending to a locked condition of the wheel. The actual slipping time, that is, the time over which the axle 9, to the electromagnet winding 2|4 of (e) Wheel-slipping occurring during application 40' the differential relay 43 decreases suiciently that the front-contact member 2 I9 and the back-contact member 2I8 of the relay 43 are actuated, respectively, to circuit-closing position and circuitopening position.

Upon the shifting of the front-contact member 2 I 9 of differential relay 43 to said closed position, the signal lamp 41 and the electromagnet 223 of the magnet valve device 46 are energized over circuits previously described. With the double beat valve 22| of the magnet valve device 46 accordingly shifted to its lower seated position, uid under pressure is immediately and rapidly vented from brake cylinder I0 to atmosphere through the exhaust port 221 of the magnet valve device Because the holding circuit for the wheel-slip relay 35 is maintained only when the back-contact member 2I8 of the diierential relay 43 is in circuit-closing position, it will be apparent that the wheel-slip relay 35 is deenergized when the y contact member 2 I8 is shifted to circuit-opening position.

Keeping in mind that under the circumstances assumed, that is, an application of the brakes initiated at a. time the train is traveling at a speed in excess' of the certain' uniform speed (40 M. P. H.), and that the relays 36 and 38 are accordingly energized initially, and the relay 31 is deenergized initially to cause the establishment of a brake cylinder pressure having a one-to-one ratio to the pressure established in the control pipe 23, it will be seen that shifting of the frontcontact member 203 of the wheel-sliprelay 35 to circuit-opening position as a result of the deenergization of the wheel-slip relay 35 as just described, interrupts the circuit for energizing the electromagnet of the relay 36. Deenergization of relay 33 results in the deenergization of the electromagnet |09 of the magnet valve device IDI, due to the interruption of the energizing circuit for electromagnet |09 by the shifting of the frontcontact member 205 of the relay 33 to circuitopening position.

The electromagnet IIB of the magnet valve device |02 remains energized, however, because the back-contact member 208 of relay 31 and the front-contact member 2|3 of the relay 38 are in circuit-closing positions. The electromagnet |28 of the magnet valve device |03 is not energized because both the back-contact member 2I4 of the relay 33 and the front-contact member 209 of the relay 31 are in circuit-opening position.

As in previously described instances, with only the eleotromagnet I I8 of the magnet valve device |02 energized, the valve mechanism iI is conditioned to reduce the brake cylinder pressure from the initially established degree to a degree having the next lower ratio with respect to the pressure in the control pipe, that is, a three-to-four ratio. Still maintaining the assumption that the pressure established in the control pipe 23 is seventy-ve pounds per sq. in., brake cylinder pressure in the brake cylinder IIJav is accordingly reduced "from the initial pressure of seventy-tive pounds per sq. in. to a pressure of approximately fifty-six pounds per sq. in.

Due to the rapidity of the response of the dilerential relay 43 and the magnet valve device 43 to the initiation of a wheel-slipping condition of Wheels 8 associated with theaxle 9, the pressure in the brake cylinder I0 is reduced at a suiciently rapid rate that before attaining a zero rotational speed corresponding to the locked position thereof, the wheels 8 on the axle 9 accelerate back to the rotational speed corresponding to the speed of travel of the train so that, as far as the wheels 8 associated with the axle 9 are concerned, wheel sliding does not occur.

When the wheels 8 on the axle 9 again attain a rotational speed substantially equivalent-to the rotational speed of the wheels 3a associated with the axle 9a, the magnetic fluxes set up by the separate electromagnet coils r2I6 and 2I1 again substantially counterbalance each other andthe relay contact members 2 I8 and 2I9 are shifted to circuit-closing and circuit-opening positions, re.. spectively. Accordingly, the signallamp 41 is extinguished and electromagnet 223 of the magnet valve device 46 is deenergized due to the shifting of the contact member 2I9 to circuit-opening position. It follows that the double beat valve 22| of the magnet valve device 46 is correspondingly returned to its upper seated position and communication between the brake cylinder I0 and the brake cylinder I0a is restored, so that the reduced pressure established in the brake cylin- The return of the back-contact member 2 I8 of the differential relay 43 to circuit-closing position, however, is without effect at this time in eiecting re-energization of the electromagnet 20| of the wheel-slip relay 35 because the contact member |96 of. the pressure switch- I1 is maintained in its upper position in contact with the contact finger |98 and out of contact with the contact finger |91. It will thus be seen that once the differential relay 43 is actuated during an application .of the brakes to effect deenergization of the electromagnet of the wheel-slip relay 35, the relay 35 is locked out against further energization even though the differential relay 43 subseqhently returns to its normal position.

As will be seen hereinafter, the only Way in which the wheel-slip relay 35 may be subsequently reenergized and the holding circuit therefor through its own contact member 202 established, is by'reducing the pressure in the control pipe 23 substantially to atmospheric pressure, which in turn amounts to complete release of the brakes.

With the wheel-slip relay 35 thus locked in its deenergizing position, the circuit for energizing the electromagnet of the relay 36 is maintained open at the contact member' 203 of relay 35, and unless the wheel slip relay 35 is reenergized in. the manner just indicatedgthe maximum pressure attainable in the brake cylinders thereafter is that determined by the condition of the valve mechanism II wherein only the electromagnet H8 of the magnet valve device |02 is energized, or in other words a three-to-four ratio with respect to the pressure established in the control pipe 23.

As in the previously described operation wherein no wheel-sliding occurred, the retardation controller I3 continues to exercise control of brake cylinder pressure dependent upon the rate of retardation of the train being within range A, range B or range C. -In view of the fact that the relays 31 and 38 are controlled by the retardation controller I3 and the governor switch device I2 independently of the Wheel-slip relay 35, it will be seen that the occurrence of a wheelslipping condition for the wheels 8 associated with the axle 9 at a time that the train is being retarded at a rate Within the range B or the range C does not result in a reduction of brake cylinder pressure from the particular ratio with respect to der I0a is also established in the brake cylinder the control pipe pressure established under the control of the retardation controller I3 and the governor switch I2.

It will thus be seen that the equipment which We have provided functions automatically to reduce the braking force, as represented by brake cylinder pressure, on all of the vehicle wheels immediately upon the occurrence of a wheel-slipping condition on a particular set of car wheels which are more heavily braked than the other car wheels. Being less heavily braked as compared to the vehicle wheels 8, it follows that the vehicle wheels 8a and the other wheels on the train cannot attain a wheel-slipping condition until after a Wheel-slipping Y condition is attained on the wheels 8. Since the equipment whichwe have provided vfunctions to prevent actual sliding of the wheels 8, it will be apparent that except in rare instances, sliding of the Wheels 8a and other similarly braked wheels of thetrain cannot occur.

In the event that the reduction of pressure in the brake cylinders |0and |0a, as automatically effected upon the slipping of the wheels 8 associated with the more heavily braked axle 3, is insufficient to prevent re-occurrence of the wheel slipping condition of the wheels 8 upon the restoration of the reduced pressure in the brake cylinder I0, no further automatic reduction in brake cylinder pressure is eiected since the relay 35 is locked in deenergized position. However, the driver or operator, observing the illumination of signal lamp 41, may effect a desired reduction in the pressure of the control' pipe 23 and thus correspondingly eiect a reduction in brake cylinder pressure, so that sliding of the wheels other than the wheels 8 may be prevented if the oper-l ator is on the alert and reduces the control pipe pressure immediately upon the illumination of the signal lamp 41.

In a similar manner if slipping of the wheels 8 associated with the axle 9 occurs when the contact finger |62 of the retardation controller Iis either the range B or range C of rates oi retardation, the operator may reduce the pressure in the control pipe and accordingly prevent sliding of the wheels of the train.'

(f) Wheel-slipping occurringv during application of the brakes initiated at a time that the train speed is less 'than a certain uniform. speed As will be recalled from previous description, the maximum initial brake cylinder pressure i which can be established in the case of an application of the brakes initiated at a time that the train is traveling at a speed below the certain uniform speed of forty miles per hour is Ilower than at speeds above this value. In this case the governor switch I2 is in circuit-opening position and the relay 38 is deenergized, only the electromagnet I0 of the magnet valve device |02 of the valve mechanism then being energized and, consequently, the maximum initial brake cylinder pressure which can be established is one which bears a three-to-four ratio to the pressure established in the control pipe. With seventyfive pounds per square inch pressure in the control pipe 23, such brake cylinder pressure is approximately nity-six pounds per square inch.

In the event that such initial brake cylinder pressure is sumciently high that the braking force exerted on the more heavily braked wheels 8 associated with the axle. begin to slip, a reduction in the brake cylinder pressure is immediately eii'ected. As will be recalled, under the conditions assumed, the electromagnet ||8 of the magnet valve device |02 is energized through a circuit including the back-contact member 2|4 of the relay 38 and the front-contact member 206 of the relay 36- Thus, when the relay 36 is deenergized, following the deenergization of the wheel-slip relay 35 as result of the slipping of the Wheels 8, the circuit for energizing the electromagnet ||8 of the magnet valve device |02 is interrupted due to the sluiting of the frontcontact member 206 of relay 36 to circuit-opening position. The relays 31 and 38 being deenergized at this time, it will be readily apparent that the electromagnets |08 and |28 of the magnet valve devices |0|.and |03 are deenergized at this time so that upon the deenergization of thel electromagnet of the magnet valve device |02, the electromagnet of each of the magnet valve devices |0i, i02 and l03 is deenergized.

As will be remembered from previous descriptions, the ratio established between brake cylin der pressure and the pressure in the control pipe 23 by the valve mechanism under such circumstances is a one-to-two ratio, which is the next lower ratio to the three-to-four ratio initially established. Thus the pressure of the uid in the brake cylinder ia and in the other similarly controlled brake cylinders associated with other Wheels of the train is automatically reduced from a three-to-four ratio to a one-to-two ratio, with respect to the control pipe pressure.

At the same time and inthe same manner as previously described for slipping of the Wheels 8 while the train was traveling at a speed in excess of the certain uniform speed of forty-miles per hour, the signal lamp 41 is illuminated and the magnet valve device 46 is actuated to vent fluid under pressure from the brake cylinder |0. Uponthe return of the wheels 8 to a rotational speed corresponding to the speed of travel of the train and substantially equivalent to the rotational speed of the wheels 8a associated with the axle 9a, the differential relay 43 is returned to its normal position wherein the signal lamp 41 is extinguished and the magnet valve device 46 again establishes communication between the brake cylinder |0 and the brake cylinder |0a. Likewise, the return of the back-contact member 2|8 of the differential relay 43 to circuitclosing position is ineffective to cause re-energization of the Wheel-slip relay 35, and the relay 35 accordingly remains locked in deenergized condition.

Thus, as in the previous case, upon the slipping of the wheels 8 the v alve mechanism is conditioned to limit the brake cylinder pressure to the next lower ratio with respect to the pressure in the control pipe 23, so that re-occurrence of the wheel-slipping condition on the wheels 8 isy unlikely.

If a slipping of the wheels 8 should occur while the train is traveling at a speed below the certain uniform speed. that is, while the governor switch |2 is in circuit-opening position, and while wheels.

EMBODIMENT SHOWN 1N Fra. 2

The embodiment represented by Fig. 2 is substantially identical to the embodiment shown in ida Fig. 1 and diders therefrom in the substitution Vof a wheel-slip relay tta in the place of the wheelfront-contact members 202 and 203, a contactmember 300 which, when the electromagnet 20| of the relay is energized, is shifted vfrom a lower circuit-closing position to an upper circuit-closing position. In its upper circuit-closing position. contact member 300 connects a Wire 26911. which is connected to the contact segment i618 of the retardation controller 3, to a wire 24th which is connected to the non-grounded terminal of the electromagnet 20'? of the relay 3l. In the lower circuit-closing position, 'thereof the contact member 30G of relay 35a. connects a wire Msc, Whichis connected to the positive terminal of the battery le through the wires 235 and 23%, to the wire Zilgb.

In operation, therefore, it will be seen that should the more heavily braked wheels 3 on the axle 9 begin to slip during an application or' the brakes, the resultant deenergization of the wheelslip relay 35a not only interrupts the energizing circuit for the relay 30 due to the shifting of the contact member 2&3 to `circuit-opening position,

but also eiects energization of electromagnet 201 of relay 3l by completing-the circuit from the positive terminal of the battery i8 to the wire Zfib through contact member 300.

The eect oi energizing the relay 3l at the same time that the relay ist is deenergized, as a result of the Wheels t beginning to slip, is to condition the valve mechanism il to limit the maximum brake cylinder pressure, thereafter efected, to the second lower ratio, with respect to the control pipe pressure, as compared t0 the first lower ratio relative to maximum initial ratio at the time that the application of the brakes is initiated eected in the embodiment shown in Fig. 1.

Should the more heavily bralsed wheels associated with the axle d begin to slip upon the initiation of an application of the brakes at a time that the .train is traveling at a speed in excess of the certain uniform speed of which the governor switch device l2 is in circuitclos ing position, it will be Yseen that the shifting of the contact member 205i of the relay d@ into circuit-opening position interrupts the circuit for energizing the electromagnet ldd of the' high magnet valve device 06 and that the shifting of the contact member 208 of the relay valto circuitopening position interrupts the circuit for energizing the electromagnet l l0 of the magnet valve device H32. In view of the fact that the backcontact member 2id of the speed relay 3@ is held in circuit-opening position, the closing of the front-contact member 20@ of relay 3l is without effect and the electromagnetig of the low magnet valve device 803 is accordingly deeenergized.

Thus, when the wheel-slip relay 35a, is deenergized in response to a slipping of the wheels 8, the valve mechanism il is changed from the initial condition thereof wherein the electromagnets of the magnet valve devices ll and db2 are energized and the electromagnet of the magnet valve device' its is deenergized, to the condition .wherein the electrcmagnets of all the magnet valve Vdevices lili, ldd and i03- are deenergized. Thus, assuming that the brake cylinder pressure initially established in the brake cylinders l@ and lila had reached its full initial one-to-one ratio with.v respect to the pressure established in the aimee? 435m. and, accordingly, as described for the em,-

bodiment shown in Fig. 1, the Wheel-slip relay 35a cannot again be energized unless the pressure in the control pipe 23 is reduced substantially to atmospheric pressure to permit the contact member ISB of the pressure switch il to reestablish the initial energizing circuit for the wheel-slip relay 35a.

Assuming that the wheel-slip relay 35a is deenergized in response to a slipping of the wheels S during an application of they brakes initiated at a time that the' train is traveling at a speed below the certainA uniform speed as determined by the governor switch device l2, it will be seen that the valve mechanism ll is changed from the initial condition thereof, wherein only the elecromagnet H8 of the intermediate magnet valve device lili is energized by' way of the back-contact 2id of speed relay 38 and the front-contact 20e of the relay 36, to the condition wherein only the electromagnet |28 of'the low magnet valve device 103 is energized. It will be apparent that the shifting of the front-contact member 23S of the relay 35 to circuit-opening position eiects deenergization of the electromagnet M8 of the intermediate magnet valve .device 602 and that the shifting of the front-contact member 2t@ of the relay 3l to circuit-closing position completes vthe circuit for energizing the electromagnet H25 ofthe low magnet valve device iBS.

Since the-maximum initial ratio between brake cylinder pressure .and pressure established in the control pipe 23 for applications of the brakes initiated at train speeds less than the certain uniform speed of forty miles per hour, is a three-tof EMBODIMENT SHowN 1N Fics. 3 AND i The embodiment shown vin. Fig. 3 is identical with the embodiment shown in Fig. 1A in many respects and diiiers from the equipment shown in Fig. 1 principally in employing a dierent type of mechanism for detecting slipping of the more heavily braked wheels associated with the axle 0. The representation of the embodiment shown in Fig. 3 is accordingly limited to only those elements which are required to point out the manner of application and operation of the different type of wheel-slip detecting means.

The equipment employed in the embodiment shown in Fig. 3 which is not employed in the embodiment shown in Fig. 1, includes a wheelslip detecting device 340, a so-called brake cylinder pressure switch device 3H, and in place of thewheel-slip relay 35, two relays 35h and 35e, respectively.

The wheel-slip detecting device 3l0 may comprise an inertia element in the form of a .dygg l ber 333 engages a lower contact member 336.

-and a torque arm 3I1 fixed to wheel 3 I 5 mounted for rotation relative to a shaft rotating with the wheels 3, such as the axle 3, by roller or ball bearings in the manner shown, a pair of resilient contact fingers 3I6 and 3I6a carried in insulated relation on the ily-wheel 3| 5,

the axle 3.

The contact iingers 3I3 and 3I3a may be of any suitable material and are secured at one end, as by screws 3I3, to an insulating member 3I3 afiixed to the ily-wheel 315 near theperiphery thereof and extending in parallel relation to the axle 3. 'I'he contact lingers 3I6 extend in parallel spaced relation past opposite sides of the axle 3 and have -suiilcient inherent vresiliency or -are biased by spring means (not shown) so that the free ends of the lingers engage in circuit-closing contact.

The torque arm 3 I 1 comprises a hub portionv 32I lilxed as by a key 326 to the axle 3 and a laterally extending portion 322 of T-shape, located in alignment with and extending into the space betweenthe contact lingers 3I3 and 3I3a, the width of the portion 322 conforming closely to the' distance between the inner faces of the contact tlngers 3I6 and 3I3a. (See Fig. 4.)

The contact fingers 3I6 and 3`I 3a are so designed and so tensioned that as long as the axle 3 is not ,rotatively accelerated or deceleratcd with respect to the fly-wheel I5 at a rate in excess of a certain rate, the contact fingers 3I6 and 3I6a remain in contact with each other against' ythe torce exerted to cause rotation of the iiywheel 3I5 with the axle 3 and wheels 3, through the medium of the torquevarm 3I1 and one of the contact lingers 3I6 or 3I6a. If the axle 3 is rotatively decelerated ata rate in excess of the certain rate, as when the wheels 3 ilxed to the axle 8 begin to slip, the .force exerted on one of the contact lingers' 3I6 and 3I3a by the torque arm 3I1 is suiiiciently great to cause separation of the contact lingers 3I6 and 3I3a and interruption of a circuit controlled thereby.

In view of the fact that contact lingers 3IIv and 3 I6a rotate with the ily-wheel 3I5, it is necessary to 4provide a pair of collector rings 323 and 323a mounted in insulated relation on the axle 9 and connected to the contact fingers 3I6 and 3I6a, respectively, as by wires 324 and 325, and a pair of suitably mounted brushes 326' cooperating respectively with the collector rings 323 and 323a.

'I'he brake cylinder pressure switch 3II is similar in construction to the pressure switch I1 ,andymay comprise a casing'containing a piston 33| having a stem 332 connected in insulated relation to a movable contact member 333. The piston 33I is subject at one side to the pressure o1' iluid in a chamber 334 which is connected, through a branch pipe 3Ib,l to that portion of the pipe BI connecting the magnet valve device 46' to the brake cylinder III associated with the more heavily braked wheels 3. Movement ot the piston 33| by the chamber 334 is yieldingly resisted by a spring 335 at the opposite side of the piston. The tension of the 'spring 335' is such that when the pressure in the chamber 334 and thus in the brake cylinder I0 is below a certain uniform' pressure, l such as ilve pounds per square inch, and sui!-v ficient to relieve slipping of the wheels 3- under any condition, piston 33I is actuated downwardly to the position shown wherein the contact mem- When the pressure of the Iluid in the chamber 334 exceeds the said certain uniform pressure,

pressure of the fluid'in the the spring 336 is overcome and the piston 33| and the contact member 333 are shifted upwardly, the contact member .333 disengaging the contact member 336 and engaging an upper contact mem- Thel contact member 343 has a lower circuitclosing position when the electromagnet 2Mb is deenergized, and an upper circuit-closing posi- Vtion when the electromagnet 2Mb is energized.

The relay 35e comprises an electromagnet'-23lc, a iront-contact member 344 a'nd a back-contact member 345.

'I'he centrifuge I 4I of governor switch device I2 is driven according to the speed of travel of the car or train, as through gears 36I connecting the centrifuge to any element which rotates according to the speed of the car or train, such as the axle 9a to which are fixed the more lightly braked wheels 3a.

The control circuits of the embodimentv represented in Fig. 3 are substantially identical to the control circuits of the embodiment shown in Fig. 1 and already described and for the sake of simplicity, only the differences relative to the embodiment shown in Fig. 1 will -be pointed out. One of the brushes 326 associated with the collector ring 323 on the axle l9,is connected by a wire 352 to a wire 353 which is in turn connected to the contact member |91 of the pressure switch I1. The other brush 326, associated with the collector ring 323:1, is connected to one terminal of the electromagnet 2Mb of the relay 35h by a wire 354 and tlie opposite terminal of the electromagnet 2Mb is connected to the negative terminal of the battery I3, as through a ground connection including the wire 234. It will thus Vbe v,

seen, that with the contact fingers 3 I3 and' 3I6ay of the wheel-slip detector 3|@ in circuit-closing contact and with 'the contact member |36 oi' the i The contact member 333 of the brake cylinder pressure switch 3II is connected'to the positive terminal of the battery I3 by a wire 366 and the wires 236 and 23|. 'The contact member 336 of the pressure switch 3II is connected by a wire 351 to the contact member 344 of .the relay 35e and to the contact member 34I of the relay 35h by the wire 351 and a branch wire 356. The contact member 331 of the pressure switch 3II is connected to the contact member 342v of the .re-I` lay 35b by a Wire 358.

In its circuit-closing position, the contact member 34| oi' the relay 35h connects the wire 353 to a wire 36| to which lone terminal of the electromagnet of the relay 35e is connected, the other terminal of the electromagnet of the relay 36c being connected to the negative terminal oi' the battery I8 as by a connection through ground in the manner indicated. It will thus be seen that with the contact member 333 of the pressure switch 3| I engaging the contact member 336, and with the wheel-slip relay 35h deenergized and the contact member 34| thereof in .circuit-closing position, a circuit is completed for energizing the electromagnet ofthe relay 36e. In its circuitclosing position, the contact member 344 ofthe relay 36e connects the wire A351 to a wire 363 which is connected to the wire 236 and thus to the positive terminal of the battery I3. 'Accordingly, it will be seen that once the electromagnet ves oi relay 35e is energized, a holding circuit is /shown'in' l to control the degree of the apestablished for maintainingthe relay energized independently of the pressure switch 3H, the holding circuit extending from the positive terminal of the battery I8 through the contact member 344 of the relay 35o, wires 351 and 358, contact member 34| of the relay 35h, electromagnet of the relay 35e, and thence to the negative terminal of the battery i3 through ground.

In itscircuit-closing position, the contact mem-- ber 342 'of the relay 35h connects the wire 353 to a wire 365 which is, in turn, connected to the back-contact member 345 of the relay-35e. lIn its. circuit-closing position, the back-contact member 345 of the relay 35o, 'connects the wire 'electromagnet oi the magnet valve device 46 is connected, the otherv terminal of the electromagnet of the magnet valve device 46 being connected goto the negative terminal ofthe battery i3, as through a ground connection in the manner shown. Thus, withA the contact member 333 of the relay 35h energized, independently -oi the 'separation of the contact member |33 of the pressure switch I1 `from-the contact member |91, it beingapparent that in its circuit-closing position, the contact-memben343 of the relay 35h connects the wire 23E and thu's the positive terminal oi the battery I3 to the wire 353 and thus to the wire 352 leading to that one'oi the brushes 326 associated with the collector ring 323 of the `wheel-slip detector device 3|0. When the electromagnet of the relay 35h is deenergized and the contactmember 343 shifted to its lower circuitclosing position, a circuit is completed from the positive terminal'of the battery I8 through the wire 238, contact member.l 343 of relay 35h, a wire 388, signal lamp 41, a wire 339 which is conriected to ground, and back through ground to 5@ the negative terminal of the battery se. since the relay 35h is normally energized, it will be apparent that the signal lamp tl is normally exy tinguished and that it is illuminated only upon the deenergization of the relay 35h as a result of separation of the contact fingers 3|@ and idof tine wheel-slip 'detector device 3m.

Operarios. or Ennonmnnr snows nv Fre. 3

rt is deemed unnecessary to describe 1n emu @n the operation of the embodiment represented in Fig. 3, since this would in large measure repeat what has already` been described inconnection with the embodiment Ashown in Fig.' l. So far as possible, therefore, onlyV those dierenes .oi operation rulting from the employment of the wheel-slip detector Si@ will be pointed out.

therefore, that the train is traveling at aspeed. or, for example, one hundred miles per hour and that an application of the brakes has been initiated by supplying uuid lat a pressure oi seventy-uve pounds per square inch to control pipe 23, it will be apparent that the valve mechanism li is controlled in identically the same man- P55 ner m previously described for the embodiment 335'to a' wire 358 to which one terminal of the plicationoi vthe brakes. v

Keeping in mind that the holding circuit through the contact member 343 of the relay 35h includes the contact fingers 3|3 and 3|6a of the wheel-slip detector 3|0, it will be seen that A should a separation of the contact lingers 3|3 and 3|5a occur as the result oi the initiation of a slipping of the wheels 8 associated with the axle 9, the relay 35h will be deenergized. Accordingly, since the contact member 333 of the brake cylinder pressure switch 3H is in its upper position engaging the contact member 331, the return of the back contact member 342 of the relay 35h to circuit-closing position completes a. circuit previously described for energizing the electromagnet of the magnet valve device 46, which is kaccordingly operated to immediately and rapidly vent uid under pressure from the brake cylinder Il applying the brakes to the wheelsB. At the same time, the shifting of the contact member 343,01' the relay 35h to its lower circuit-closing position causes the signal lamp 41 to be. illuminated to indicatethe slipping of theV wheels 3.

At the Sametime also, the shifting of the iront contact member 20317 of the relay 35h to circuitopeningvpositicn, interrupts the circuit through the contact inger I 62 and contact segment |33 of the retardation controller i3 whereby the relay 36 was energized, ,thus effecting deenergization of the high train wire 3| in the same manner as previously described for shifting of the contact` member 203 of thel relay 35 oi' Fig. l to circuitopening position upon a slipping oi the wheels l. Accordingly, the valve mechanism is conditioned tolimit'the subsequent pressure for the Vbrake cylinder Illa, as wellas the brake cylinder I0 to a degree corresponding to the next lower ratio with respect to the pressure established in the control pipe 23. On the basis of the ratios between brake cylinder pressure and control pipe pressure determined by the valve mechanism Il as previouslyassumed, it will be seen that the valve mechanism. Il is conditioned to limit the subsequent maximum ratio between brake cylinder premure and the pressure in the control pipe 23 to a three-to-four ratio insteadof the maximum or -one-to-one ratio.u

When the reduction of the pressure ofthe fluid in the brake cylinder Gd, as eected by the magnet valve device 6, is sumcient to cause the wheels 8 to accelerate back toward a rotational speed corresponding to the speed of travel of the train and the pressure switch 3M is correspondingly actuated from its upper to its lower circuitclosing position wherein the Contact member 333 thereof engages contact member 333; the circuit 33?, and due-to the energization of the relay Sic and the consequent establishment of the holding circuit therefor through the contact member 344 of the relay 35e and the back-contact member 84B of the relay 35h, previously described, the rmgnet valve device 43 is prevented from being further energized es long as the relay 35h remains deenergized, due to'the back-contact member 345 of relay 35e being held in circuit-opening position. Reengagement oi the contact ngers3|6 and 3|6a of the wheel-slip detector 3|0, following the return of the wheels 8 of the rotational speed corresponding to the speed of travel of the train is, however, ineffective to cause re-energization of the relay 35h since with the seventy-live pounds per square inch pressure maintained in the control pipe-23, the contact member |96 of the pressure switch 1 is out of engagement with the contact member |91. Thus, the initial circuit for energizing the relay 35h cannot be completed unless the pressure in the control pipe 23 is reduced substantially to atmospheric pressure, and the brakes thereby substantially released, to permit the Contact member |96 to reengage the contact member |91, in which case the relay 35h `is energized so that the holding circuit therefor is again set up through the contact member 343 of the relay 35h, and the signal lamp 41 is extin-l guished.

If, upon a slipping of the wheels 8, the engineman or operator of the car or train does not reduce the pressure established in the control pipe 23, the relay 35h accordingly remains deenergized and consequently the relay 35e remains energized over the holding circuit including the front-contact member 344 of the relay 35e and the backcontact member 34| of the relay 35h, regardless of the fact that the contact member 333 of the brake cylinder pressure switch 3| is again shifted, by the restoration of pressure in the brake -cylinder I0 following the deenergization of the magnet valve device 46, out of engagement with the contact member 336. With the back-contact member 345 of the relay 35e thus held in circuitopening position, the reengagement oi the contact member 333 of the pressure switch 3| with the contact member 331, as a result of the restoration of the pressure in the brake cylinder I0, is ineffective to complete the circuit for energizing the magnet valve device 46. Thus, the magnet valve device 46 remains deenergized for the remainder of the application of the brakes, assumlng nor reduction in the established pressure in the control pipe 23, so that the pressure reestablished in the brake cylinder |0 bears thelnext lower ratio from the maximum ratio with respect to the pressure established in the control pipe 23 If slipping of the wheels plication of the brakes initiated at a time that the train is traveling at a speed less than the certain uniform speed of forty miles per hour as determined bythe setting of the governor switch device I2, the deenergization of the relay 35h as a result of the separation of the contact fingers 3| 6 and 3|6a of the wheel-slip detector 3||J operaltes',- in the same manner as does the opening of the contact member 203 of the relay 35 of Fig. 1 under the same condition, to so condition the valve mechanism as to limit the brake cylinder pressure to the next lower ratio with respect to -the pressure in the control pipe 23. As will be vfour ratio. It will thus be seen that slipping oi the wheels 8 in the embodiment shown in Fig. 3`

will similarly cause the valve mechanism tobe conditioned to limit brake cylinder pressure during the remainder of the application to a one-tothe brakes automatically both 8 occurs upon an ap- `member to the relay 35h, corresponding to the contact member 300 of the relay 35a shown in Fig. 2, whereby relay 31 will be energized at the same time that the relay 36 is deenergized.

ADAPTION or INVENTION 'ro A TRAIN BRAKE CONTROL SYSTEM The manner in which our invention is adapted to control the brakes on a train of cars of either the articulated or the non-articulated type should.

be readily apparent. Obviously, the brake cylinders for applying the brakes on wheel-and-axle units not shown in the drawings are respectively under the control of valve mechanisms corresponding to the valve mechanism I the magnet valve devices |0I, |02, and |03 of each valve mechanism being respectively connected to the train wires 3|, 32 and 33.

Furthermore, it should be obvious that additional governor switch devices similar to the governor switch device |2 shown in the drawings may be privided in parallel connected relation for insuring the proper control of the valve mechanisms in the event of failure of one of the governor switch devices.

It will be understood that instead of providing a main reservoir pipe 22 in the manner shown, local supply reservoirs may be provided at intervals along the length of the train, and charged in any suitable manner either from the brake pipe or from another supply pipe whereby an adequate and immediately available supply of iiuid under pressure is assured for each brake cylinder along the length of the train.

SUMMARY summarizing, it will be seen that we have disclosed several embodiments of a brake control equipment effective to control the application of according to the speed of the train and according to the rate of retardation of the train, and including means whereby the degree of the application of the brakes is automatically and rapidly decreased and limited to a reduced degree upon the occurrence of wheel-slipping, so as to prevent wheelslipping and so as to render recurrence of wheel- 'slipping unlikely.

By associating wheel-slip detecting means with a particular set of wheels which is more heavily braked than the remaining sets of wheels on the train, the automatic reduction and limitation of the degree of the brake application precedes the possible occurrence of the wheel-slipping or wheel-sliding condition on the sets of wheels other than the more heavily braked set' of wheels.

The embodiments shown in Figs. 1 and 3 effect a certain reduction in brake cylinder pressure from that established initially when a slipping of the more heavily braked wheels occurs, While the embodiment shown in Fig. 2 causes a greater reduction in brake cylinder pressure upon a slipping of the more heavily braked wheels.

It will be understood that while we have shown and described our invention Illustratively in certain specic forms, certain omissions, additions or modifications may be effected in the embodil brake control means.-

. slipping of a vehicle Wheel, the speed-responsive means and the wheel-slip `responsive means being jointly eiectiveto control the operation of 'the 2. In a car or train brake-system, in combination, brake control means adapted to control the supply and release of fluid under pressure for controlling the degree of braking force with which the-brakes are applied-means responsive to the rate of retardation of the train, means responsive to the speed of the train, and means operatively responsive only to the slipping of a car wheel, the retardation-responsive means, the speed-responsive means, and the wheel-slip responsive means all being effective to control the operation of the brake control means.

3. In -a vehicle or train brake system, in combination, a brake cylinder, a normally uncharged pipe chargeable with fluid under pressure, brake control means variously conditionable to cause a plurality of certain diierent uniform ratios between the pressure established in the said pipe and the pressure in the brake cylinder, means responsive to the rate of retardation of the train for conditioning said brake controlmeans diierently for different rates of retardation of the'train and thereby causing different r-atios between the pressure established in the control pipe and the pressure in the brake cylinder, and means operatively responsive only to the slipping of a vehiclewheel for conditioning the said brake control means to cause it to establish a lower ratio between the pressure in the brake cylinder and the pressure in the said pipe than that effected under the sole control of the said retardationresponsive means.

4. In a vehicle or train brake system, in combination, a brake cylinder, a normally uncharged pipe chargeable with fluid at different pressures, brake control means veriously conditionable to effect a plurality of certain different uniform ratios between the pressure established in the said pipe and the pressure in the brake cylinder. means responsive to the speed of the train for variously conditioning said brake control means to cause it to establish one of the certain uniform ratios at one speed and another of said uniform ratios at another speed, andmeans responsive to the slipping of a vehicle wheel for varying the condition of the said brake control means to effect a diierent ratio between the pressure in the brake cylinder and the pressure established in the said pipe than that determined solely under the control of the said speed-responsive means.

5. In a vehicle or train brake system, in combination, a brake cylinder, a normally uncharged pipe chargeable with fluid at diierent pressures, a brake control means variously conditionable to cause a plurality of certain different uniform ratios between the pressure established in the said pipe and the pressure established in the brake cylinder, means responsive to variations in the rate of retardation of the train for variously conditioning the brake control means as to cause it to eiect one of said certain ratios at one rate of retardation and a diierent one of said certain ratios at another rate of retardation, means responsive to variations in the speed of the train for variously conditioning the brake control means to cause it to establish different ones of said certain ratios between the brake cylinder pressure and the pressure inthe said pipe dependent upon the speed of the train, and means responsive to the slipping of a vehicle wheel for also varying the condition of the brake control means to cause it to establish diierent ratios between the brake cylinder pressure and the presplication of the brakes on one wheel of the train, a second brake cylinder for' eiecting application of the brakes on a second wheel of the train, brake control meansior controlling the supply of uid under pressure to and the release of fluid' under pressure from both of said brake cylinders, means responsive to the slipping oi said one train wheel, independent means controlled by the said Wheel-slip responsive means and eiective upon the slipping of the said one wheel for rapidly reducing the pressure in only the said rst brake cylinder to prevent sliding of the said one wheel, said brake control means being controlled by the wheel-slip responsive means so as to reduce the pressure in the second brake cylinder and to limit the pressure obtainable in both the brake Y cylinders for the remainder of the -application of the brakes after slipping of the said one wheel ceases, to a maximum pressure which is less than the brake cylinder pressure at the time that the said one train wheel begins to slip.

7. In a vehicle or train brake system, in corn- Abination, a rst brake cylinder for eiecting application of the brakes on one wheel of the train with a certain degree of braking force for a given pressure in the brake cylinder, a second brake cylinder for eiecting application of the brakes on a diierent wheel of the train with a lesser degree of braking force for the said given pressure of iluid therein, brake control means for controlling the supply uid under pressure to r and the release of fluid under pressure from both of said brake cylinders, means responsive to the slipping of the said one train wheel, independent means controlled by the said wheel-slip responsive lmeans and effective upon the slipping of the said one Wheel for rapidly reducing the pressure in only the said first brake cylinder to reduce the degree of braking forcel on the said one wheel and thus to prevent sliding of the said one wheel, said brake control means being controlled by the wheel-slip responsive means so as to reduce the pressure in said second brake cylinder and to limit the maximum pressure attainable in both the brake cylinders for the remainder of the application of the brakes after slipping of the said one wheel ceases to a pressure which is less than the maximum initially attainable prior to the slipping of the said one train wheel.

Ain

8. In a vehicle or train brake system, in' com- 

